thanks to ncnn ❤

be903e2 over 2 years ago

68 kB

	syntax = "proto2";

	package caffe;

	// Specifies the shape (dimensions) of a Blob.
	message BlobShape {
	repeated int64 dim = 1 [packed = true];
	}

	message BlobProto {
	optional BlobShape shape = 7;
	repeated float data = 5 [packed = true];
	repeated float diff = 6 [packed = true];
	repeated double double_data = 8 [packed = true];
	repeated double double_diff = 9 [packed = true];

	// 4D dimensions -- deprecated. Use "shape" instead.
	optional int32 num = 1 [default = 0];
	optional int32 channels = 2 [default = 0];
	optional int32 height = 3 [default = 0];
	optional int32 width = 4 [default = 0];
	}

	// The BlobProtoVector is simply a way to pass multiple blobproto instances
	// around.
	message BlobProtoVector {
	repeated BlobProto blobs = 1;
	}

	message Datum {
	optional int32 channels = 1;
	optional int32 height = 2;
	optional int32 width = 3;
	// the actual image data, in bytes
	optional bytes data = 4;
	optional int32 label = 5;
	// Optionally, the datum could also hold float data.
	repeated float float_data = 6;
	// If true data contains an encoded image that need to be decoded
	optional bool encoded = 7 [default = false];
	}

	message FillerParameter {
	// The filler type.
	optional string type = 1 [default = 'constant'];
	optional float value = 2 [default = 0]; // the value in constant filler
	optional float min = 3 [default = 0]; // the min value in uniform filler
	optional float max = 4 [default = 1]; // the max value in uniform filler
	optional float mean = 5 [default = 0]; // the mean value in Gaussian filler
	optional float std = 6 [default = 1]; // the std value in Gaussian filler
	// The expected number of non-zero output weights for a given input in
	// Gaussian filler -- the default -1 means don't perform sparsification.
	optional int32 sparse = 7 [default = -1];
	// Normalize the filler variance by fan_in, fan_out, or their average.
	// Applies to 'xavier' and 'msra' fillers.
	enum VarianceNorm {
	FAN_IN = 0;
	FAN_OUT = 1;
	AVERAGE = 2;
	}
	optional VarianceNorm variance_norm = 8 [default = FAN_IN];
	}

	message NetParameter {
	optional string name = 1; // consider giving the network a name
	// DEPRECATED. See InputParameter. The input blobs to the network.
	repeated string input = 3;
	// DEPRECATED. See InputParameter. The shape of the input blobs.
	repeated BlobShape input_shape = 8;

	// 4D input dimensions -- deprecated. Use "input_shape" instead.
	// If specified, for each input blob there should be four
	// values specifying the num, channels, height and width of the input blob.
	// Thus, there should be a total of (4 * #input) numbers.
	repeated int32 input_dim = 4;

	// Whether the network will force every layer to carry out backward operation.
	// If set False, then whether to carry out backward is determined
	// automatically according to the net structure and learning rates.
	optional bool force_backward = 5 [default = false];
	// The current "state" of the network, including the phase, level, and stage.
	// Some layers may be included/excluded depending on this state and the states
	// specified in the layers' include and exclude fields.
	optional NetState state = 6;

	// Print debugging information about results while running Net::Forward,
	// Net::Backward, and Net::Update.
	optional bool debug_info = 7 [default = false];

	// The layers that make up the net. Each of their configurations, including
	// connectivity and behavior, is specified as a LayerParameter.
	repeated LayerParameter layer = 100; // ID 100 so layers are printed last.

	// DEPRECATED: use 'layer' instead.
	repeated V1LayerParameter layers = 2;
	}

	// NOTE
	// Update the next available ID when you add a new SolverParameter field.
	//
	// SolverParameter next available ID: 41 (last added: type)
	message SolverParameter {
	//////////////////////////////////////////////////////////////////////////////
	// Specifying the train and test networks
	//
	// Exactly one train net must be specified using one of the following fields:
	// train_net_param, train_net, net_param, net
	// One or more test nets may be specified using any of the following fields:
	// test_net_param, test_net, net_param, net
	// If more than one test net field is specified (e.g., both net and
	// test_net are specified), they will be evaluated in the field order given
	// above: (1) test_net_param, (2) test_net, (3) net_param/net.
	// A test_iter must be specified for each test_net.
	// A test_level and/or a test_stage may also be specified for each test_net.
	//////////////////////////////////////////////////////////////////////////////

	// Proto filename for the train net, possibly combined with one or more
	// test nets.
	optional string net = 24;
	// Inline train net param, possibly combined with one or more test nets.
	optional NetParameter net_param = 25;

	optional string train_net = 1; // Proto filename for the train net.
	repeated string test_net = 2; // Proto filenames for the test nets.
	optional NetParameter train_net_param = 21; // Inline train net params.
	repeated NetParameter test_net_param = 22; // Inline test net params.

	// The states for the train/test nets. Must be unspecified or
	// specified once per net.
	//
	// By default, all states will have solver = true;
	// train_state will have phase = TRAIN,
	// and all test_state's will have phase = TEST.
	// Other defaults are set according to the NetState defaults.
	optional NetState train_state = 26;
	repeated NetState test_state = 27;

	// The number of iterations for each test net.
	repeated int32 test_iter = 3;

	// The number of iterations between two testing phases.
	optional int32 test_interval = 4 [default = 0];
	optional bool test_compute_loss = 19 [default = false];
	// If true, run an initial test pass before the first iteration,
	// ensuring memory availability and printing the starting value of the loss.
	optional bool test_initialization = 32 [default = true];
	optional float base_lr = 5; // The base learning rate
	// the number of iterations between displaying info. If display = 0, no info
	// will be displayed.
	optional int32 display = 6;
	// Display the loss averaged over the last average_loss iterations
	optional int32 average_loss = 33 [default = 1];
	optional int32 max_iter = 7; // the maximum number of iterations
	// accumulate gradients over `iter_size` x `batch_size` instances
	optional int32 iter_size = 36 [default = 1];

	// The learning rate decay policy. The currently implemented learning rate
	// policies are as follows:
	// - fixed: always return base_lr.
	// - step: return base_lr * gamma ^ (floor(iter / step))
	// - exp: return base_lr * gamma ^ iter
	// - inv: return base_lr * (1 + gamma * iter) ^ (- power)
	// - multistep: similar to step but it allows non uniform steps defined by
	// stepvalue
	// - poly: the effective learning rate follows a polynomial decay, to be
	// zero by the max_iter. return base_lr (1 - iter/max_iter) ^ (power)
	// - sigmoid: the effective learning rate follows a sigmod decay
	// return base_lr ( 1/(1 + exp(-gamma * (iter - stepsize))))
	//
	// where base_lr, max_iter, gamma, step, stepvalue and power are defined
	// in the solver parameter protocol buffer, and iter is the current iteration.
	optional string lr_policy = 8;
	optional float gamma = 9; // The parameter to compute the learning rate.
	optional float power = 10; // The parameter to compute the learning rate.
	optional float momentum = 11; // The momentum value.
	optional float weight_decay = 12; // The weight decay.
	// regularization types supported: L1 and L2
	// controlled by weight_decay
	optional string regularization_type = 29 [default = "L2"];
	// the stepsize for learning rate policy "step"
	optional int32 stepsize = 13;
	// the stepsize for learning rate policy "multistep"
	repeated int32 stepvalue = 34;

	// Set clip_gradients to >= 0 to clip parameter gradients to that L2 norm,
	// whenever their actual L2 norm is larger.
	optional float clip_gradients = 35 [default = -1];

	optional int32 snapshot = 14 [default = 0]; // The snapshot interval
	optional string snapshot_prefix = 15; // The prefix for the snapshot.
	// whether to snapshot diff in the results or not. Snapshotting diff will help
	// debugging but the final protocol buffer size will be much larger.
	optional bool snapshot_diff = 16 [default = false];
	enum SnapshotFormat {
	HDF5 = 0;
	BINARYPROTO = 1;
	}
	optional SnapshotFormat snapshot_format = 37 [default = BINARYPROTO];
	// the mode solver will use: 0 for CPU and 1 for GPU. Use GPU in default.
	enum SolverMode {
	CPU = 0;
	GPU = 1;
	}
	optional SolverMode solver_mode = 17 [default = GPU];
	// the device_id will that be used in GPU mode. Use device_id = 0 in default.
	optional int32 device_id = 18 [default = 0];
	// If non-negative, the seed with which the Solver will initialize the Caffe
	// random number generator -- useful for reproducible results. Otherwise,
	// (and by default) initialize using a seed derived from the system clock.
	optional int64 random_seed = 20 [default = -1];

	// type of the solver
	optional string type = 40 [default = "SGD"];

	// numerical stability for RMSProp, AdaGrad and AdaDelta and Adam
	optional float delta = 31 [default = 1e-8];
	// parameters for the Adam solver
	optional float momentum2 = 39 [default = 0.999];

	// RMSProp decay value
	// MeanSquare(t) = rms_decayMeanSquare(t-1) + (1-rms_decay)SquareGradient(t)
	optional float rms_decay = 38;

	// If true, print information about the state of the net that may help with
	// debugging learning problems.
	optional bool debug_info = 23 [default = false];

	// If false, don't save a snapshot after training finishes.
	optional bool snapshot_after_train = 28 [default = true];

	// DEPRECATED: old solver enum types, use string instead
	enum SolverType {
	SGD = 0;
	NESTEROV = 1;
	ADAGRAD = 2;
	RMSPROP = 3;
	ADADELTA = 4;
	ADAM = 5;
	}
	// DEPRECATED: use type instead of solver_type
	optional SolverType solver_type = 30 [default = SGD];
	}

	// A message that stores the solver snapshots
	message SolverState {
	optional int32 iter = 1; // The current iteration
	optional string learned_net = 2; // The file that stores the learned net.
	repeated BlobProto history = 3; // The history for sgd solvers
	optional int32 current_step = 4 [default = 0]; // The current step for learning rate
	}

	enum Phase {
	TRAIN = 0;
	TEST = 1;
	}

	message NetState {
	optional Phase phase = 1 [default = TEST];
	optional int32 level = 2 [default = 0];
	repeated string stage = 3;
	}

	message NetStateRule {
	// Set phase to require the NetState have a particular phase (TRAIN or TEST)
	// to meet this rule.
	optional Phase phase = 1;

	// Set the minimum and/or maximum levels in which the layer should be used.
	// Leave undefined to meet the rule regardless of level.
	optional int32 min_level = 2;
	optional int32 max_level = 3;

	// Customizable sets of stages to include or exclude.
	// The net must have ALL of the specified stages and NONE of the specified
	// "not_stage"s to meet the rule.
	// (Use multiple NetStateRules to specify conjunctions of stages.)
	repeated string stage = 4;
	repeated string not_stage = 5;
	}

	// Specifies training parameters (multipliers on global learning constants,
	// and the name and other settings used for weight sharing).
	message ParamSpec {
	// The names of the parameter blobs -- useful for sharing parameters among
	// layers, but never required otherwise. To share a parameter between two
	// layers, give it a (non-empty) name.
	optional string name = 1;

	// Whether to require shared weights to have the same shape, or just the same
	// count -- defaults to STRICT if unspecified.
	optional DimCheckMode share_mode = 2;
	enum DimCheckMode {
	// STRICT (default) requires that num, channels, height, width each match.
	STRICT = 0;
	// PERMISSIVE requires only the count (numchannelsheight*width) to match.
	PERMISSIVE = 1;
	}

	// The multiplier on the global learning rate for this parameter.
	optional float lr_mult = 3 [default = 1.0];

	// The multiplier on the global weight decay for this parameter.
	optional float decay_mult = 4 [default = 1.0];
	}

	// NOTE
	// Update the next available ID when you add a new LayerParameter field.
	//
	// LayerParameter next available layer-specific ID: 146 (last added: shuffle_channel_param)
	message LayerParameter {
	optional string name = 1; // the layer name
	optional string type = 2; // the layer type
	repeated string bottom = 3; // the name of each bottom blob
	repeated string top = 4; // the name of each top blob

	// The train / test phase for computation.
	optional Phase phase = 10;

	// The amount of weight to assign each top blob in the objective.
	// Each layer assigns a default value, usually of either 0 or 1,
	// to each top blob.
	repeated float loss_weight = 5;

	// Specifies training parameters (multipliers on global learning constants,
	// and the name and other settings used for weight sharing).
	repeated ParamSpec param = 6;

	// The blobs containing the numeric parameters of the layer.
	repeated BlobProto blobs = 7;

	// Specifies whether to backpropagate to each bottom. If unspecified,
	// Caffe will automatically infer whether each input needs backpropagation
	// to compute parameter gradients. If set to true for some inputs,
	// backpropagation to those inputs is forced; if set false for some inputs,
	// backpropagation to those inputs is skipped.
	//
	// The size must be either 0 or equal to the number of bottoms.
	repeated bool propagate_down = 11;

	// Rules controlling whether and when a layer is included in the network,
	// based on the current NetState. You may specify a non-zero number of rules
	// to include OR exclude, but not both. If no include or exclude rules are
	// specified, the layer is always included. If the current NetState meets
	// ANY (i.e., one or more) of the specified rules, the layer is
	// included/excluded.
	repeated NetStateRule include = 8;
	repeated NetStateRule exclude = 9;

	// Parameters for data pre-processing.
	optional TransformationParameter transform_param = 100;

	// Parameters shared by loss layers.
	optional LossParameter loss_param = 101;

	// Layer type-specific parameters.
	//
	// Note: certain layers may have more than one computational engine
	// for their implementation. These layers include an Engine type and
	// engine parameter for selecting the implementation.
	// The default for the engine is set by the ENGINE switch at compile-time.
	optional AccuracyParameter accuracy_param = 102;
	optional ArgMaxParameter argmax_param = 103;
	optional BatchNormParameter batch_norm_param = 139;
	optional BiasParameter bias_param = 141;
	optional BNParameter bn_param = 45;
	optional ConcatParameter concat_param = 104;
	optional ContrastiveLossParameter contrastive_loss_param = 105;
	optional ConvolutionParameter convolution_param = 106;
	optional CropParameter crop_param = 144;
	optional DataParameter data_param = 107;
	optional DetectionOutputParameter detection_output_param = 204;
	optional YoloDetectionOutputParameter yolo_detection_output_param = 601;
	optional Yolov3DetectionOutputParameter yolov3_detection_output_param = 603;
	optional DropoutParameter dropout_param = 108;
	optional DummyDataParameter dummy_data_param = 109;
	optional EltwiseParameter eltwise_param = 110;
	optional ELUParameter elu_param = 140;
	optional EmbedParameter embed_param = 137;
	optional ExpParameter exp_param = 111;
	optional FlattenParameter flatten_param = 135;
	optional HDF5DataParameter hdf5_data_param = 112;
	optional HDF5OutputParameter hdf5_output_param = 113;
	optional HingeLossParameter hinge_loss_param = 114;
	optional ImageDataParameter image_data_param = 115;
	optional InfogainLossParameter infogain_loss_param = 116;
	optional InnerProductParameter inner_product_param = 117;
	optional InputParameter input_param = 143;
	optional InterpParameter interp_param = 205;
	optional LogParameter log_param = 134;
	optional LRNParameter lrn_param = 118;
	optional MemoryDataParameter memory_data_param = 119;
	optional MVNParameter mvn_param = 120;
	optional NormalizeParameter norm_param = 206;
	optional PoolingParameter pooling_param = 121;
	optional PermuteParameter permute_param = 202;
	optional PowerParameter power_param = 122;
	optional PReLUParameter prelu_param = 131;
	optional PriorBoxParameter prior_box_param = 203;
	optional PSROIPoolingParameter psroi_pooling_param = 149;
	optional PythonParameter python_param = 130;
	optional RecurrentParameter recurrent_param = 146;
	optional ReductionParameter reduction_param = 136;
	optional ReLUParameter relu_param = 123;
	optional ReorgParameter reorg_param = 147;
	optional ReshapeParameter reshape_param = 133;
	optional ROIAlignParameter roi_align_param = 148;
	optional ROIPoolingParameter roi_pooling_param = 8266711;
	optional ScaleParameter scale_param = 142;
	optional ShuffleChannelParameter shuffle_channel_param = 145;
	optional SigmoidParameter sigmoid_param = 124;
	optional SmoothL1LossParameter smooth_l1_loss_param = 8266712;
	optional SoftmaxParameter softmax_param = 125;
	optional SPPParameter spp_param = 132;
	optional SliceParameter slice_param = 126;
	optional TanHParameter tanh_param = 127;
	optional ThresholdParameter threshold_param = 128;
	optional TileParameter tile_param = 138;
	optional WindowDataParameter window_data_param = 129;
	}

	// Message that stores parameters used to apply transformation
	// to the data layer's data
	message TransformationParameter {
	// For data pre-processing, we can do simple scaling and subtracting the
	// data mean, if provided. Note that the mean subtraction is always carried
	// out before scaling.
	optional float scale = 1 [default = 1];
	// Specify if we want to randomly mirror data.
	optional bool mirror = 2 [default = false];
	// Specify if we would like to randomly crop an image.
	optional uint32 crop_size = 3 [default = 0];
	// mean_file and mean_value cannot be specified at the same time
	optional string mean_file = 4;
	// if specified can be repeated once (would substract it from all the channels)
	// or can be repeated the same number of times as channels
	// (would subtract them from the corresponding channel)
	repeated float mean_value = 5;
	// Force the decoded image to have 3 color channels.
	optional bool force_color = 6 [default = false];
	// Force the decoded image to have 1 color channels.
	optional bool force_gray = 7 [default = false];
	}

	// Message that stores parameters used by data transformer for resize policy
	message ResizeParameter {
	//Probability of using this resize policy
	optional float prob = 1 [default = 1];

	enum Resize_mode {
	WARP = 1;
	FIT_SMALL_SIZE = 2;
	FIT_LARGE_SIZE_AND_PAD = 3;
	}
	optional Resize_mode resize_mode = 2 [default = WARP];
	optional uint32 height = 3 [default = 0];
	optional uint32 width = 4 [default = 0];
	// A parameter used to update bbox in FIT_SMALL_SIZE mode.
	optional uint32 height_scale = 8 [default = 0];
	optional uint32 width_scale = 9 [default = 0];

	enum Pad_mode {
	CONSTANT = 1;
	MIRRORED = 2;
	REPEAT_NEAREST = 3;
	}
	// Padding mode for BE_SMALL_SIZE_AND_PAD mode and object centering
	optional Pad_mode pad_mode = 5 [default = CONSTANT];
	// if specified can be repeated once (would fill all the channels)
	// or can be repeated the same number of times as channels
	// (would use it them to the corresponding channel)
	repeated float pad_value = 6;

	enum Interp_mode { //Same as in OpenCV
	LINEAR = 1;
	AREA = 2;
	NEAREST = 3;
	CUBIC = 4;
	LANCZOS4 = 5;
	}
	//interpolation for for resizing
	repeated Interp_mode interp_mode = 7;
	}

	// Message that stores parameters shared by loss layers
	message LossParameter {
	// If specified, ignore instances with the given label.
	optional int32 ignore_label = 1;
	// How to normalize the loss for loss layers that aggregate across batches,
	// spatial dimensions, or other dimensions. Currently only implemented in
	// SoftmaxWithLoss layer.
	enum NormalizationMode {
	// Divide by the number of examples in the batch times spatial dimensions.
	// Outputs that receive the ignore label will NOT be ignored in computing
	// the normalization factor.
	FULL = 0;
	// Divide by the total number of output locations that do not take the
	// ignore_label. If ignore_label is not set, this behaves like FULL.
	VALID = 1;
	// Divide by the batch size.
	BATCH_SIZE = 2;
	// Do not normalize the loss.
	NONE = 3;
	}
	optional NormalizationMode normalization = 3 [default = VALID];
	// Deprecated. Ignored if normalization is specified. If normalization
	// is not specified, then setting this to false will be equivalent to
	// normalization = BATCH_SIZE to be consistent with previous behavior.
	optional bool normalize = 2;
	}

	// Messages that store parameters used by individual layer types follow, in
	// alphabetical order.

	message AccuracyParameter {
	// When computing accuracy, count as correct by comparing the true label to
	// the top k scoring classes. By default, only compare to the top scoring
	// class (i.e. argmax).
	optional uint32 top_k = 1 [default = 1];

	// The "label" axis of the prediction blob, whose argmax corresponds to the
	// predicted label -- may be negative to index from the end (e.g., -1 for the
	// last axis). For example, if axis == 1 and the predictions are
	// (N x C x H x W), the label blob is expected to contain NHW ground truth
	// labels with integer values in {0, 1, ..., C-1}.
	optional int32 axis = 2 [default = 1];

	// If specified, ignore instances with the given label.
	optional int32 ignore_label = 3;
	}

	message ArgMaxParameter {
	// If true produce pairs (argmax, maxval)
	optional bool out_max_val = 1 [default = false];
	optional uint32 top_k = 2 [default = 1];
	// The axis along which to maximise -- may be negative to index from the
	// end (e.g., -1 for the last axis).
	// By default ArgMaxLayer maximizes over the flattened trailing dimensions
	// for each index of the first / num dimension.
	optional int32 axis = 3;
	}

	message ConcatParameter {
	// The axis along which to concatenate -- may be negative to index from the
	// end (e.g., -1 for the last axis). Other axes must have the
	// same dimension for all the bottom blobs.
	// By default, ConcatLayer concatenates blobs along the "channels" axis (1).
	optional int32 axis = 2 [default = 1];

	// DEPRECATED: alias for "axis" -- does not support negative indexing.
	optional uint32 concat_dim = 1 [default = 1];
	}

	message BatchNormParameter {
	// If false, accumulate global mean/variance values via a moving average. If
	// true, use those accumulated values instead of computing mean/variance
	// across the batch.
	optional bool use_global_stats = 1;
	// How much does the moving average decay each iteration?
	optional float moving_average_fraction = 2 [default = .999];
	// Small value to add to the variance estimate so that we don't divide by
	// zero.
	optional float eps = 3 [default = 1e-5];
	}

	message BiasParameter {
	// The first axis of bottom[0] (the first input Blob) along which to apply
	// bottom[1] (the second input Blob). May be negative to index from the end
	// (e.g., -1 for the last axis).
	//
	// For example, if bottom[0] is 4D with shape 100x3x40x60, the output
	// top[0] will have the same shape, and bottom[1] may have any of the
	// following shapes (for the given value of axis):
	// (axis == 0 == -4) 100; 100x3; 100x3x40; 100x3x40x60
	// (axis == 1 == -3) 3; 3x40; 3x40x60
	// (axis == 2 == -2) 40; 40x60
	// (axis == 3 == -1) 60
	// Furthermore, bottom[1] may have the empty shape (regardless of the value of
	// "axis") -- a scalar bias.
	optional int32 axis = 1 [default = 1];

	// (num_axes is ignored unless just one bottom is given and the bias is
	// a learned parameter of the layer. Otherwise, num_axes is determined by the
	// number of axes by the second bottom.)
	// The number of axes of the input (bottom[0]) covered by the bias
	// parameter, or -1 to cover all axes of bottom[0] starting from `axis`.
	// Set num_axes := 0, to add a zero-axis Blob: a scalar.
	optional int32 num_axes = 2 [default = 1];

	// (filler is ignored unless just one bottom is given and the bias is
	// a learned parameter of the layer.)
	// The initialization for the learned bias parameter.
	// Default is the zero (0) initialization, resulting in the BiasLayer
	// initially performing the identity operation.
	optional FillerParameter filler = 3;
	}

	// Message that stores parameters used by BN (Batch Normalization) layer
	message BNParameter {
	enum BNMode {
	LEARN = 0;
	INFERENCE = 1;
	}
	optional BNMode bn_mode = 3 [default = LEARN];
	optional FillerParameter scale_filler = 1; // The filler for the scale
	optional FillerParameter shift_filler = 2; // The filler for the shift
	}

	message ContrastiveLossParameter {
	// margin for dissimilar pair
	optional float margin = 1 [default = 1.0];
	// The first implementation of this cost did not exactly match the cost of
	// Hadsell et al 2006 -- using (margin - d^2) instead of (margin - d)^2.
	// legacy_version = false (the default) uses (margin - d)^2 as proposed in the
	// Hadsell paper. New models should probably use this version.
	// legacy_version = true uses (margin - d^2). This is kept to support /
	// reproduce existing models and results
	optional bool legacy_version = 2 [default = false];
	}

	message ConvolutionParameter {
	optional uint32 num_output = 1; // The number of outputs for the layer
	optional bool bias_term = 2 [default = true]; // whether to have bias terms

	// Pad, kernel size, and stride are all given as a single value for equal
	// dimensions in all spatial dimensions, or once per spatial dimension.
	repeated uint32 pad = 3; // The padding size; defaults to 0
	repeated uint32 kernel_size = 4; // The kernel size
	repeated uint32 stride = 6; // The stride; defaults to 1
	// Factor used to dilate the kernel, (implicitly) zero-filling the resulting
	// holes. (Kernel dilation is sometimes referred to by its use in the
	// algorithme à trous from Holschneider et al. 1987.)
	repeated uint32 dilation = 18; // The dilation; defaults to 1

	// For 2D convolution only, the _h and _w versions may also be used to
	// specify both spatial dimensions.
	optional uint32 pad_h = 9 [default = 0]; // The padding height (2D only)
	optional uint32 pad_w = 10 [default = 0]; // The padding width (2D only)
	optional uint32 kernel_h = 11; // The kernel height (2D only)
	optional uint32 kernel_w = 12; // The kernel width (2D only)
	optional uint32 stride_h = 13; // The stride height (2D only)
	optional uint32 stride_w = 14; // The stride width (2D only)

	optional uint32 group = 5 [default = 1]; // The group size for group conv

	optional FillerParameter weight_filler = 7; // The filler for the weight
	optional FillerParameter bias_filler = 8; // The filler for the bias
	enum Engine {
	DEFAULT = 0;
	CAFFE = 1;
	CUDNN = 2;
	}
	optional Engine engine = 15 [default = DEFAULT];

	// The axis to interpret as "channels" when performing convolution.
	// Preceding dimensions are treated as independent inputs;
	// succeeding dimensions are treated as "spatial".
	// With (N, C, H, W) inputs, and axis == 1 (the default), we perform
	// N independent 2D convolutions, sliding C-channel (or (C/g)-channels, for
	// groups g>1) filters across the spatial axes (H, W) of the input.
	// With (N, C, D, H, W) inputs, and axis == 1, we perform
	// N independent 3D convolutions, sliding (C/g)-channels
	// filters across the spatial axes (D, H, W) of the input.
	optional int32 axis = 16 [default = 1];

	// Whether to force use of the general ND convolution, even if a specific
	// implementation for blobs of the appropriate number of spatial dimensions
	// is available. (Currently, there is only a 2D-specific convolution
	// implementation; for input blobs with num_axes != 2, this option is
	// ignored and the ND implementation will be used.)
	optional bool force_nd_im2col = 17 [default = false];
	}

	message CropParameter {
	// To crop, elements of the first bottom are selected to fit the dimensions
	// of the second, reference bottom. The crop is configured by
	// - the crop `axis` to pick the dimensions for cropping
	// - the crop `offset` to set the shift for all/each dimension
	// to align the cropped bottom with the reference bottom.
	// All dimensions up to but excluding `axis` are preserved, while
	// the dimensions including and trailing `axis` are cropped.
	// If only one `offset` is set, then all dimensions are offset by this amount.
	// Otherwise, the number of offsets must equal the number of cropped axes to
	// shift the crop in each dimension accordingly.
	// Note: standard dimensions are N,C,H,W so the default is a spatial crop,
	// and `axis` may be negative to index from the end (e.g., -1 for the last
	// axis).
	optional int32 axis = 1 [default = 2];
	repeated uint32 offset = 2;
	}

	message DataParameter {
	enum DB {
	LEVELDB = 0;
	LMDB = 1;
	}
	// Specify the data source.
	optional string source = 1;
	// Specify the batch size.
	optional uint32 batch_size = 4;
	// The rand_skip variable is for the data layer to skip a few data points
	// to avoid all asynchronous sgd clients to start at the same point. The skip
	// point would be set as rand_skip * rand(0,1). Note that rand_skip should not
	// be larger than the number of keys in the database.
	// DEPRECATED. Each solver accesses a different subset of the database.
	optional uint32 rand_skip = 7 [default = 0];
	optional DB backend = 8 [default = LEVELDB];
	// DEPRECATED. See TransformationParameter. For data pre-processing, we can do
	// simple scaling and subtracting the data mean, if provided. Note that the
	// mean subtraction is always carried out before scaling.
	optional float scale = 2 [default = 1];
	optional string mean_file = 3;
	// DEPRECATED. See TransformationParameter. Specify if we would like to randomly
	// crop an image.
	optional uint32 crop_size = 5 [default = 0];
	// DEPRECATED. See TransformationParameter. Specify if we want to randomly mirror
	// data.
	optional bool mirror = 6 [default = false];
	// Force the encoded image to have 3 color channels
	optional bool force_encoded_color = 9 [default = false];
	// Prefetch queue (Number of batches to prefetch to host memory, increase if
	// data access bandwidth varies).
	optional uint32 prefetch = 10 [default = 4];
	}

	message NonMaximumSuppressionParameter {
	// Threshold to be used in nms.
	optional float nms_threshold = 1 [default = 0.3];
	// Maximum number of results to be kept.
	optional int32 top_k = 2;
	// Parameter for adaptive nms.
	optional float eta = 3 [default = 1.0];
	}

	message SaveOutputParameter {
	// Output directory. If not empty, we will save the results.
	optional string output_directory = 1;
	// Output name prefix.
	optional string output_name_prefix = 2;
	// Output format.
	// VOC - PASCAL VOC output format.
	// COCO - MS COCO output format.
	optional string output_format = 3;
	// If you want to output results, must also provide the following two files.
	// Otherwise, we will ignore saving results.
	// label map file.
	optional string label_map_file = 4;
	// A file which contains a list of names and sizes with same order
	// of the input DB. The file is in the following format:
	// name height width
	// ...
	optional string name_size_file = 5;
	// Number of test images. It can be less than the lines specified in
	// name_size_file. For example, when we only want to evaluate on part
	// of the test images.
	optional uint32 num_test_image = 6;
	// The resize parameter used in saving the data.
	optional ResizeParameter resize_param = 7;
	}

	// Message that store parameters used by DetectionOutputLayer
	message DetectionOutputParameter {
	// Number of classes to be predicted. Required!
	optional uint32 num_classes = 1;
	// If true, bounding box are shared among different classes.
	optional bool share_location = 2 [default = true];
	// Background label id. If there is no background class,
	// set it as -1.
	optional int32 background_label_id = 3 [default = 0];
	// Parameters used for non maximum suppression.
	optional NonMaximumSuppressionParameter nms_param = 4;
	// Parameters used for saving detection results.
	optional SaveOutputParameter save_output_param = 5;
	// Type of coding method for bbox.
	optional PriorBoxParameter.CodeType code_type = 6 [default = CORNER];
	// If true, variance is encoded in target; otherwise we need to adjust the
	// predicted offset accordingly.
	optional bool variance_encoded_in_target = 8 [default = false];
	// Number of total bboxes to be kept per image after nms step.
	// -1 means keeping all bboxes after nms step.
	optional int32 keep_top_k = 7 [default = -1];
	// Only consider detections whose confidences are larger than a threshold.
	// If not provided, consider all boxes.
	optional float confidence_threshold = 9;
	// If true, visualize the detection results.
	optional bool visualize = 10 [default = false];
	// The threshold used to visualize the detection results.
	optional float visualize_threshold = 11;
	// If provided, save outputs to video file.
	optional string save_file = 12;
	}

	message YoloDetectionOutputParameter {
	// Yolo detection output layer
	optional uint32 side = 1 [default = 13];
	optional uint32 num_classes = 2 [default = 20];
	optional uint32 num_box = 3 [default = 5];
	optional uint32 coords = 4 [default = 4];
	optional float confidence_threshold = 5 [default = 0.01];
	optional float nms_threshold = 6 [default = 0.45];
	repeated float biases = 7;
	optional string label_map_file = 8;
	}
	message Yolov3DetectionOutputParameter {
	// Yolov3 detection output layer
	// Yolo detection output layer
	optional uint32 num_classes = 1 [default = 20];
	optional uint32 num_box = 2 [default = 3];
	optional float confidence_threshold = 3 [default = 0.01];
	optional float nms_threshold = 4 [default = 0.45];
	repeated float biases = 5;
	repeated uint32 anchors_scale = 6 ;
	optional uint32 mask_group_num = 7 [default = 2];
	repeated uint32 mask = 8;
	}
	message DropoutParameter {
	optional float dropout_ratio = 1 [default = 0.5]; // dropout ratio
	optional bool scale_train = 2 [default = true]; // scale train or test phase
	}

	// DummyDataLayer fills any number of arbitrarily shaped blobs with random
	// (or constant) data generated by "Fillers" (see "message FillerParameter").
	message DummyDataParameter {
	// This layer produces N >= 1 top blobs. DummyDataParameter must specify 1 or N
	// shape fields, and 0, 1 or N data_fillers.
	//
	// If 0 data_fillers are specified, ConstantFiller with a value of 0 is used.
	// If 1 data_filler is specified, it is applied to all top blobs. If N are
	// specified, the ith is applied to the ith top blob.
	repeated FillerParameter data_filler = 1;
	repeated BlobShape shape = 6;

	// 4D dimensions -- deprecated. Use "shape" instead.
	repeated uint32 num = 2;
	repeated uint32 channels = 3;
	repeated uint32 height = 4;
	repeated uint32 width = 5;
	}

	message EltwiseParameter {
	enum EltwiseOp {
	PROD = 0;
	SUM = 1;
	MAX = 2;
	}
	optional EltwiseOp operation = 1 [default = SUM]; // element-wise operation
	repeated float coeff = 2; // blob-wise coefficient for SUM operation

	// Whether to use an asymptotically slower (for >2 inputs) but stabler method
	// of computing the gradient for the PROD operation. (No effect for SUM op.)
	optional bool stable_prod_grad = 3 [default = true];
	}

	// Message that stores parameters used by ELULayer
	message ELUParameter {
	// Described in:
	// Clevert, D.-A., Unterthiner, T., & Hochreiter, S. (2015). Fast and Accurate
	// Deep Network Learning by Exponential Linear Units (ELUs). arXiv
	optional float alpha = 1 [default = 1];
	}

	// Message that stores parameters used by EmbedLayer
	message EmbedParameter {
	optional uint32 num_output = 1; // The number of outputs for the layer
	// The input is given as integers to be interpreted as one-hot
	// vector indices with dimension num_input. Hence num_input should be
	// 1 greater than the maximum possible input value.
	optional uint32 input_dim = 2;

	optional bool bias_term = 3 [default = true]; // Whether to use a bias term
	optional FillerParameter weight_filler = 4; // The filler for the weight
	optional FillerParameter bias_filler = 5; // The filler for the bias

	}

	// Message that stores parameters used by ExpLayer
	message ExpParameter {
	// ExpLayer computes outputs y = base ^ (shift + scale * x), for base > 0.
	// Or if base is set to the default (-1), base is set to e,
	// so y = exp(shift + scale * x).
	optional float base = 1 [default = -1.0];
	optional float scale = 2 [default = 1.0];
	optional float shift = 3 [default = 0.0];
	}

	/// Message that stores parameters used by FlattenLayer
	message FlattenParameter {
	// The first axis to flatten: all preceding axes are retained in the output.
	// May be negative to index from the end (e.g., -1 for the last axis).
	optional int32 axis = 1 [default = 1];

	// The last axis to flatten: all following axes are retained in the output.
	// May be negative to index from the end (e.g., the default -1 for the last
	// axis).
	optional int32 end_axis = 2 [default = -1];
	}

	// Message that stores parameters used by HDF5DataLayer
	message HDF5DataParameter {
	// Specify the data source.
	optional string source = 1;
	// Specify the batch size.
	optional uint32 batch_size = 2;

	// Specify whether to shuffle the data.
	// If shuffle == true, the ordering of the HDF5 files is shuffled,
	// and the ordering of data within any given HDF5 file is shuffled,
	// but data between different files are not interleaved; all of a file's
	// data are output (in a random order) before moving onto another file.
	optional bool shuffle = 3 [default = false];
	}

	message HDF5OutputParameter {
	optional string file_name = 1;
	}

	message HingeLossParameter {
	enum Norm {
	L1 = 1;
	L2 = 2;
	}
	// Specify the Norm to use L1 or L2
	optional Norm norm = 1 [default = L1];
	}

	message ImageDataParameter {
	// Specify the data source.
	optional string source = 1;
	// Specify the batch size.
	optional uint32 batch_size = 4 [default = 1];
	// The rand_skip variable is for the data layer to skip a few data points
	// to avoid all asynchronous sgd clients to start at the same point. The skip
	// point would be set as rand_skip * rand(0,1). Note that rand_skip should not
	// be larger than the number of keys in the database.
	optional uint32 rand_skip = 7 [default = 0];
	// Whether or not ImageLayer should shuffle the list of files at every epoch.
	optional bool shuffle = 8 [default = false];
	// It will also resize images if new_height or new_width are not zero.
	optional uint32 new_height = 9 [default = 0];
	optional uint32 new_width = 10 [default = 0];
	// Specify if the images are color or gray
	optional bool is_color = 11 [default = true];
	// DEPRECATED. See TransformationParameter. For data pre-processing, we can do
	// simple scaling and subtracting the data mean, if provided. Note that the
	// mean subtraction is always carried out before scaling.
	optional float scale = 2 [default = 1];
	optional string mean_file = 3;
	// DEPRECATED. See TransformationParameter. Specify if we would like to randomly
	// crop an image.
	optional uint32 crop_size = 5 [default = 0];
	// DEPRECATED. See TransformationParameter. Specify if we want to randomly mirror
	// data.
	optional bool mirror = 6 [default = false];
	optional string root_folder = 12 [default = ""];
	}

	message InfogainLossParameter {
	// Specify the infogain matrix source.
	optional string source = 1;
	}

	message InnerProductParameter {
	optional uint32 num_output = 1; // The number of outputs for the layer
	optional bool bias_term = 2 [default = true]; // whether to have bias terms
	optional FillerParameter weight_filler = 3; // The filler for the weight
	optional FillerParameter bias_filler = 4; // The filler for the bias

	// The first axis to be lumped into a single inner product computation;
	// all preceding axes are retained in the output.
	// May be negative to index from the end (e.g., -1 for the last axis).
	optional int32 axis = 5 [default = 1];
	// Specify whether to transpose the weight matrix or not.
	// If transpose == true, any operations will be performed on the transpose
	// of the weight matrix. The weight matrix itself is not going to be transposed
	// but rather the transfer flag of operations will be toggled accordingly.
	optional bool transpose = 6 [default = false];
	}

	message InputParameter {
	// This layer produces N >= 1 top blob(s) to be assigned manually.
	// Define N shapes to set a shape for each top.
	// Define 1 shape to set the same shape for every top.
	// Define no shape to defer to reshaping manually.
	repeated BlobShape shape = 1;
	}
	message InterpParameter {
	optional int32 height = 1 [default = 0]; // Height of output
	optional int32 width = 2 [default = 0]; // Width of output
	optional int32 zoom_factor = 3 [default = 1]; // zoom factor
	optional int32 shrink_factor = 4 [default = 1]; // shrink factor
	optional int32 pad_beg = 5 [default = 0]; // padding at begin of input
	optional int32 pad_end = 6 [default = 0]; // padding at end of input
	}
	// Message that stores parameters used by LogLayer
	message LogParameter {
	// LogLayer computes outputs y = log_base(shift + scale * x), for base > 0.
	// Or if base is set to the default (-1), base is set to e,
	// so y = ln(shift + scale * x) = log_e(shift + scale * x)
	optional float base = 1 [default = -1.0];
	optional float scale = 2 [default = 1.0];
	optional float shift = 3 [default = 0.0];
	}

	// Message that stores parameters used by LRNLayer
	message LRNParameter {
	optional uint32 local_size = 1 [default = 5];
	optional float alpha = 2 [default = 1.];
	optional float beta = 3 [default = 0.75];
	enum NormRegion {
	ACROSS_CHANNELS = 0;
	WITHIN_CHANNEL = 1;
	}
	optional NormRegion norm_region = 4 [default = ACROSS_CHANNELS];
	optional float k = 5 [default = 1.];
	enum Engine {
	DEFAULT = 0;
	CAFFE = 1;
	CUDNN = 2;
	}
	optional Engine engine = 6 [default = DEFAULT];
	}

	message MemoryDataParameter {
	optional uint32 batch_size = 1;
	optional uint32 channels = 2;
	optional uint32 height = 3;
	optional uint32 width = 4;
	}

	message MVNParameter {
	// This parameter can be set to false to normalize mean only
	optional bool normalize_variance = 1 [default = true];

	// This parameter can be set to true to perform DNN-like MVN
	optional bool across_channels = 2 [default = false];

	// Epsilon for not dividing by zero while normalizing variance
	optional float eps = 3 [default = 1e-9];
	}

	// Message that stores parameters used by NormalizeLayer
	message NormalizeParameter {
	optional bool across_spatial = 1 [default = true];
	// Initial value of scale. Default is 1.0 for all
	optional FillerParameter scale_filler = 2;
	// Whether or not scale parameters are shared across channels.
	optional bool channel_shared = 3 [default = true];
	// Epsilon for not dividing by zero while normalizing variance
	optional float eps = 4 [default = 1e-10];
	}

	message PermuteParameter {
	// The new orders of the axes of data. Notice it should be with
	// in the same range as the input data, and it starts from 0.
	// Do not provide repeated order.
	repeated uint32 order = 1;
	}

	message PoolingParameter {
	enum PoolMethod {
	MAX = 0;
	AVE = 1;
	STOCHASTIC = 2;
	}
	optional PoolMethod pool = 1 [default = MAX]; // The pooling method
	// Pad, kernel size, and stride are all given as a single value for equal
	// dimensions in height and width or as Y, X pairs.
	optional uint32 pad = 4 [default = 0]; // The padding size (equal in Y, X)
	optional uint32 pad_h = 9 [default = 0]; // The padding height
	optional uint32 pad_w = 10 [default = 0]; // The padding width
	optional uint32 kernel_size = 2; // The kernel size (square)
	optional uint32 kernel_h = 5; // The kernel height
	optional uint32 kernel_w = 6; // The kernel width
	optional uint32 stride = 3 [default = 1]; // The stride (equal in Y, X)
	optional uint32 stride_h = 7; // The stride height
	optional uint32 stride_w = 8; // The stride width
	enum Engine {
	DEFAULT = 0;
	CAFFE = 1;
	CUDNN = 2;
	}
	optional Engine engine = 11 [default = DEFAULT];
	// If global_pooling then it will pool over the size of the bottom by doing
	// kernel_h = bottom->height and kernel_w = bottom->width
	optional bool global_pooling = 12 [default = false];
	}

	message PowerParameter {
	// PowerLayer computes outputs y = (shift + scale * x) ^ power.
	optional float power = 1 [default = 1.0];
	optional float scale = 2 [default = 1.0];
	optional float shift = 3 [default = 0.0];
	}

	// Message that store parameters used by PriorBoxLayer
	message PriorBoxParameter {
	// Encode/decode type.
	enum CodeType {
	CORNER = 1;
	CENTER_SIZE = 2;
	CORNER_SIZE = 3;
	}
	// Minimum box size (in pixels). Required!
	repeated float min_size = 1;
	// Maximum box size (in pixels). Required!
	repeated float max_size = 2;
	// Various of aspect ratios. Duplicate ratios will be ignored.
	// If none is provided, we use default ratio 1.
	repeated float aspect_ratio = 3;
	// If true, will flip each aspect ratio.
	// For example, if there is aspect ratio "r",
	// we will generate aspect ratio "1.0/r" as well.
	optional bool flip = 4 [default = true];
	// If true, will clip the prior so that it is within [0, 1]
	optional bool clip = 5 [default = false];
	// Variance for adjusting the prior bboxes.
	repeated float variance = 6;
	// By default, we calculate img_height, img_width, step_x, step_y based on
	// bottom[0] (feat) and bottom[1] (img). Unless these values are explicitly
	// provided.
	// Explicitly provide the img_size.
	optional uint32 img_size = 7;
	// Either img_size or img_h/img_w should be specified; not both.
	optional uint32 img_h = 8;
	optional uint32 img_w = 9;

	// Explicitly provide the step size.
	optional float step = 10;
	// Either step or step_h/step_w should be specified; not both.
	optional float step_h = 11;
	optional float step_w = 12;

	// Offset to the top left corner of each cell.
	optional float offset = 13 [default = 0.5];
	}

	message PSROIPoolingParameter {
	required float spatial_scale = 1;
	required int32 output_dim = 2; // output channel number
	required int32 group_size = 3; // number of groups to encode position-sensitive score maps
	}

	message PythonParameter {
	optional string module = 1;
	optional string layer = 2;
	// This value is set to the attribute `param_str` of the `PythonLayer` object
	// in Python before calling the `setup()` method. This could be a number,
	// string, dictionary in Python dict format, JSON, etc. You may parse this
	// string in `setup` method and use it in `forward` and `backward`.
	optional string param_str = 3 [default = ''];
	// Whether this PythonLayer is shared among worker solvers during data parallelism.
	// If true, each worker solver sequentially run forward from this layer.
	// This value should be set true if you are using it as a data layer.
	optional bool share_in_parallel = 4 [default = false];
	}

	// Message that stores parameters used by RecurrentLayer
	message RecurrentParameter {
	// The dimension of the output (and usually hidden state) representation --
	// must be explicitly set to non-zero.
	optional uint32 num_output = 1 [default = 0];

	optional FillerParameter weight_filler = 2; // The filler for the weight
	optional FillerParameter bias_filler = 3; // The filler for the bias

	// Whether to enable displaying debug_info in the unrolled recurrent net.
	optional bool debug_info = 4 [default = false];

	// Whether to add as additional inputs (bottoms) the initial hidden state
	// blobs, and add as additional outputs (tops) the final timestep hidden state
	// blobs. The number of additional bottom/top blobs required depends on the
	// recurrent architecture -- e.g., 1 for RNNs, 2 for LSTMs.
	optional bool expose_hidden = 5 [default = false];
	}

	// Message that stores parameters used by ReductionLayer
	message ReductionParameter {
	enum ReductionOp {
	SUM = 1;
	ASUM = 2;
	SUMSQ = 3;
	MEAN = 4;
	}

	optional ReductionOp operation = 1 [default = SUM]; // reduction operation

	// The first axis to reduce to a scalar -- may be negative to index from the
	// end (e.g., -1 for the last axis).
	// (Currently, only reduction along ALL "tail" axes is supported; reduction
	// of axis M through N, where N < num_axes - 1, is unsupported.)
	// Suppose we have an n-axis bottom Blob with shape:
	// (d0, d1, d2, ..., d(m-1), dm, d(m+1), ..., d(n-1)).
	// If axis == m, the output Blob will have shape
	// (d0, d1, d2, ..., d(m-1)),
	// and the ReductionOp operation is performed (d0 * d1 * d2 * ... * d(m-1))
	// times, each including (dm * d(m+1) * ... * d(n-1)) individual data.
	// If axis == 0 (the default), the output Blob always has the empty shape
	// (count 1), performing reduction across the entire input --
	// often useful for creating new loss functions.
	optional int32 axis = 2 [default = 0];

	optional float coeff = 3 [default = 1.0]; // coefficient for output
	}

	// Message that stores parameters used by ReLULayer
	message ReLUParameter {
	// Allow non-zero slope for negative inputs to speed up optimization
	// Described in:
	// Maas, A. L., Hannun, A. Y., & Ng, A. Y. (2013). Rectifier nonlinearities
	// improve neural network acoustic models. In ICML Workshop on Deep Learning
	// for Audio, Speech, and Language Processing.
	optional float negative_slope = 1 [default = 0];
	enum Engine {
	DEFAULT = 0;
	CAFFE = 1;
	CUDNN = 2;
	}
	optional Engine engine = 2 [default = DEFAULT];
	}

	message ReorgParameter {
	optional uint32 stride = 1;
	optional bool reverse = 2 [default = false];
	}

	message ReshapeParameter {
	// Specify the output dimensions. If some of the dimensions are set to 0,
	// the corresponding dimension from the bottom layer is used (unchanged).
	// Exactly one dimension may be set to -1, in which case its value is
	// inferred from the count of the bottom blob and the remaining dimensions.
	// For example, suppose we want to reshape a 2D blob "input" with shape 2 x 8:
	//
	// layer {
	// type: "Reshape" bottom: "input" top: "output"
	// reshape_param { ... }
	// }
	//
	// If "input" is 2D with shape 2 x 8, then the following reshape_param
	// specifications are all equivalent, producing a 3D blob "output" with shape
	// 2 x 2 x 4:
	//
	// reshape_param { shape { dim: 2 dim: 2 dim: 4 } }
	// reshape_param { shape { dim: 0 dim: 2 dim: 4 } }
	// reshape_param { shape { dim: 0 dim: 2 dim: -1 } }
	// reshape_param { shape { dim: -1 dim: 0 dim: 2 } }
	//
	optional BlobShape shape = 1;

	// axis and num_axes control the portion of the bottom blob's shape that are
	// replaced by (included in) the reshape. By default (axis == 0 and
	// num_axes == -1), the entire bottom blob shape is included in the reshape,
	// and hence the shape field must specify the entire output shape.
	//
	// axis may be non-zero to retain some portion of the beginning of the input
	// shape (and may be negative to index from the end; e.g., -1 to begin the
	// reshape after the last axis, including nothing in the reshape,
	// -2 to include only the last axis, etc.).
	//
	// For example, suppose "input" is a 2D blob with shape 2 x 8.
	// Then the following ReshapeLayer specifications are all equivalent,
	// producing a blob "output" with shape 2 x 2 x 4:
	//
	// reshape_param { shape { dim: 2 dim: 2 dim: 4 } }
	// reshape_param { shape { dim: 2 dim: 4 } axis: 1 }
	// reshape_param { shape { dim: 2 dim: 4 } axis: -3 }
	//
	// num_axes specifies the extent of the reshape.
	// If num_axes >= 0 (and axis >= 0), the reshape will be performed only on
	// input axes in the range [axis, axis+num_axes].
	// num_axes may also be -1, the default, to include all remaining axes
	// (starting from axis).
	//
	// For example, suppose "input" is a 2D blob with shape 2 x 8.
	// Then the following ReshapeLayer specifications are equivalent,
	// producing a blob "output" with shape 1 x 2 x 8.
	//
	// reshape_param { shape { dim: 1 dim: 2 dim: 8 } }
	// reshape_param { shape { dim: 1 dim: 2 } num_axes: 1 }
	// reshape_param { shape { dim: 1 } num_axes: 0 }
	//
	// On the other hand, these would produce output blob shape 2 x 1 x 8:
	//
	// reshape_param { shape { dim: 2 dim: 1 dim: 8 } }
	// reshape_param { shape { dim: 1 } axis: 1 num_axes: 0 }
	//
	optional int32 axis = 2 [default = 0];
	optional int32 num_axes = 3 [default = -1];
	}

	message ROIAlignParameter {
	// Pad, kernel size, and stride are all given as a single value for equal
	// dimensions in height and width or as Y, X pairs.
	optional uint32 pooled_h = 1 [default = 0]; // The pooled output height
	optional uint32 pooled_w = 2 [default = 0]; // The pooled output width
	// Multiplicative spatial scale factor to translate ROI coords from their
	// input scale to the scale used when pooling
	optional float spatial_scale = 3 [default = 1];
	}

	// Message that stores parameters used by ROIPoolingLayer
	message ROIPoolingParameter {
	// Pad, kernel size, and stride are all given as a single value for equal
	// dimensions in height and width or as Y, X pairs.
	optional uint32 pooled_h = 1 [default = 0]; // The pooled output height
	optional uint32 pooled_w = 2 [default = 0]; // The pooled output width
	// Multiplicative spatial scale factor to translate ROI coords from their
	// input scale to the scale used when pooling
	optional float spatial_scale = 3 [default = 1];
	}

	message ScaleParameter {
	// The first axis of bottom[0] (the first input Blob) along which to apply
	// bottom[1] (the second input Blob). May be negative to index from the end
	// (e.g., -1 for the last axis).
	//
	// For example, if bottom[0] is 4D with shape 100x3x40x60, the output
	// top[0] will have the same shape, and bottom[1] may have any of the
	// following shapes (for the given value of axis):
	// (axis == 0 == -4) 100; 100x3; 100x3x40; 100x3x40x60
	// (axis == 1 == -3) 3; 3x40; 3x40x60
	// (axis == 2 == -2) 40; 40x60
	// (axis == 3 == -1) 60
	// Furthermore, bottom[1] may have the empty shape (regardless of the value of
	// "axis") -- a scalar multiplier.
	optional int32 axis = 1 [default = 1];

	// (num_axes is ignored unless just one bottom is given and the scale is
	// a learned parameter of the layer. Otherwise, num_axes is determined by the
	// number of axes by the second bottom.)
	// The number of axes of the input (bottom[0]) covered by the scale
	// parameter, or -1 to cover all axes of bottom[0] starting from `axis`.
	// Set num_axes := 0, to multiply with a zero-axis Blob: a scalar.
	optional int32 num_axes = 2 [default = 1];

	// (filler is ignored unless just one bottom is given and the scale is
	// a learned parameter of the layer.)
	// The initialization for the learned scale parameter.
	// Default is the unit (1) initialization, resulting in the ScaleLayer
	// initially performing the identity operation.
	optional FillerParameter filler = 3;

	// Whether to also learn a bias (equivalent to a ScaleLayer+BiasLayer, but
	// may be more efficient). Initialized with bias_filler (defaults to 0).
	optional bool bias_term = 4 [default = false];
	optional FillerParameter bias_filler = 5;
	}

	message ShuffleChannelParameter {
	// first introduced by
	// "ShuffleNet: An Extremely Efficient Convolutional Neural Network
	// for Mobile Devices"
	optional uint32 group = 1[default = 1]; // The number of group
	}

	message SigmoidParameter {
	enum Engine {
	DEFAULT = 0;
	CAFFE = 1;
	CUDNN = 2;
	}
	optional Engine engine = 1 [default = DEFAULT];
	}

	message SmoothL1LossParameter {
	// SmoothL1Loss(x) =
	// 0.5 * (sigma * x) ** 2 -- if x < 1.0 / sigma / sigma
	// \|x\| - 0.5 / sigma / sigma -- otherwise
	optional float sigma = 1 [default = 1];
	}

	message SliceParameter {
	// The axis along which to slice -- may be negative to index from the end
	// (e.g., -1 for the last axis).
	// By default, SliceLayer concatenates blobs along the "channels" axis (1).
	optional int32 axis = 3 [default = 1];
	repeated uint32 slice_point = 2;

	// DEPRECATED: alias for "axis" -- does not support negative indexing.
	optional uint32 slice_dim = 1 [default = 1];
	}

	// Message that stores parameters used by SoftmaxLayer, SoftmaxWithLossLayer
	message SoftmaxParameter {
	enum Engine {
	DEFAULT = 0;
	CAFFE = 1;
	CUDNN = 2;
	}
	optional Engine engine = 1 [default = DEFAULT];

	// The axis along which to perform the softmax -- may be negative to index
	// from the end (e.g., -1 for the last axis).
	// Any other axes will be evaluated as independent softmaxes.
	optional int32 axis = 2 [default = 1];
	}

	message TanHParameter {
	enum Engine {
	DEFAULT = 0;
	CAFFE = 1;
	CUDNN = 2;
	}
	optional Engine engine = 1 [default = DEFAULT];
	}

	// Message that stores parameters used by TileLayer
	message TileParameter {
	// The index of the axis to tile.
	optional int32 axis = 1 [default = 1];

	// The number of copies (tiles) of the blob to output.
	optional int32 tiles = 2;
	}

	// Message that stores parameters used by ThresholdLayer
	message ThresholdParameter {
	optional float threshold = 1 [default = 0]; // Strictly positive values
	}

	message WindowDataParameter {
	// Specify the data source.
	optional string source = 1;
	// For data pre-processing, we can do simple scaling and subtracting the
	// data mean, if provided. Note that the mean subtraction is always carried
	// out before scaling.
	optional float scale = 2 [default = 1];
	optional string mean_file = 3;
	// Specify the batch size.
	optional uint32 batch_size = 4;
	// Specify if we would like to randomly crop an image.
	optional uint32 crop_size = 5 [default = 0];
	// Specify if we want to randomly mirror data.
	optional bool mirror = 6 [default = false];
	// Foreground (object) overlap threshold
	optional float fg_threshold = 7 [default = 0.5];
	// Background (non-object) overlap threshold
	optional float bg_threshold = 8 [default = 0.5];
	// Fraction of batch that should be foreground objects
	optional float fg_fraction = 9 [default = 0.25];
	// Amount of contextual padding to add around a window
	// (used only by the window_data_layer)
	optional uint32 context_pad = 10 [default = 0];
	// Mode for cropping out a detection window
	// warp: cropped window is warped to a fixed size and aspect ratio
	// square: the tightest square around the window is cropped
	optional string crop_mode = 11 [default = "warp"];
	// cache_images: will load all images in memory for faster access
	optional bool cache_images = 12 [default = false];
	// append root_folder to locate images
	optional string root_folder = 13 [default = ""];
	}

	message SPPParameter {
	enum PoolMethod {
	MAX = 0;
	AVE = 1;
	STOCHASTIC = 2;
	}
	optional uint32 pyramid_height = 1;
	optional PoolMethod pool = 2 [default = MAX]; // The pooling method
	enum Engine {
	DEFAULT = 0;
	CAFFE = 1;
	CUDNN = 2;
	}
	optional Engine engine = 6 [default = DEFAULT];
	}

	// DEPRECATED: use LayerParameter.
	message V1LayerParameter {
	repeated string bottom = 2;
	repeated string top = 3;
	optional string name = 4;
	repeated NetStateRule include = 32;
	repeated NetStateRule exclude = 33;
	enum LayerType {
	NONE = 0;
	ABSVAL = 35;
	ACCURACY = 1;
	ARGMAX = 30;
	BNLL = 2;
	CONCAT = 3;
	CONTRASTIVE_LOSS = 37;
	CONVOLUTION = 4;
	DATA = 5;
	DECONVOLUTION = 39;
	DROPOUT = 6;
	DUMMY_DATA = 32;
	EUCLIDEAN_LOSS = 7;
	ELTWISE = 25;
	EXP = 38;
	FLATTEN = 8;
	HDF5_DATA = 9;
	HDF5_OUTPUT = 10;
	HINGE_LOSS = 28;
	IM2COL = 11;
	IMAGE_DATA = 12;
	INFOGAIN_LOSS = 13;
	INNER_PRODUCT = 14;
	LRN = 15;
	MEMORY_DATA = 29;
	MULTINOMIAL_LOGISTIC_LOSS = 16;
	MVN = 34;
	POOLING = 17;
	POWER = 26;
	RELU = 18;
	SIGMOID = 19;
	SIGMOID_CROSS_ENTROPY_LOSS = 27;
	SILENCE = 36;
	SOFTMAX = 20;
	SOFTMAX_LOSS = 21;
	SPLIT = 22;
	SLICE = 33;
	TANH = 23;
	WINDOW_DATA = 24;
	THRESHOLD = 31;
	}
	optional LayerType type = 5;
	repeated BlobProto blobs = 6;
	repeated string param = 1001;
	repeated DimCheckMode blob_share_mode = 1002;
	enum DimCheckMode {
	STRICT = 0;
	PERMISSIVE = 1;
	}
	repeated float blobs_lr = 7;
	repeated float weight_decay = 8;
	repeated float loss_weight = 35;
	optional AccuracyParameter accuracy_param = 27;
	optional ArgMaxParameter argmax_param = 23;
	optional ConcatParameter concat_param = 9;
	optional ContrastiveLossParameter contrastive_loss_param = 40;
	optional ConvolutionParameter convolution_param = 10;
	optional DataParameter data_param = 11;
	optional DropoutParameter dropout_param = 12;
	optional DummyDataParameter dummy_data_param = 26;
	optional EltwiseParameter eltwise_param = 24;
	optional ExpParameter exp_param = 41;
	optional HDF5DataParameter hdf5_data_param = 13;
	optional HDF5OutputParameter hdf5_output_param = 14;
	optional HingeLossParameter hinge_loss_param = 29;
	optional ImageDataParameter image_data_param = 15;
	optional InfogainLossParameter infogain_loss_param = 16;
	optional InnerProductParameter inner_product_param = 17;
	optional LRNParameter lrn_param = 18;
	optional MemoryDataParameter memory_data_param = 22;
	optional MVNParameter mvn_param = 34;
	optional PoolingParameter pooling_param = 19;
	optional PowerParameter power_param = 21;
	optional ReLUParameter relu_param = 30;
	optional SigmoidParameter sigmoid_param = 38;
	optional SoftmaxParameter softmax_param = 39;
	optional SliceParameter slice_param = 31;
	optional TanHParameter tanh_param = 37;
	optional ThresholdParameter threshold_param = 25;
	optional WindowDataParameter window_data_param = 20;
	optional TransformationParameter transform_param = 36;
	optional LossParameter loss_param = 42;
	optional V0LayerParameter layer = 1;
	}

	// DEPRECATED: V0LayerParameter is the old way of specifying layer parameters
	// in Caffe. We keep this message type around for legacy support.
	message V0LayerParameter {
	optional string name = 1; // the layer name
	optional string type = 2; // the string to specify the layer type

	// Parameters to specify layers with inner products.
	optional uint32 num_output = 3; // The number of outputs for the layer
	optional bool biasterm = 4 [default = true]; // whether to have bias terms
	optional FillerParameter weight_filler = 5; // The filler for the weight
	optional FillerParameter bias_filler = 6; // The filler for the bias

	optional uint32 pad = 7 [default = 0]; // The padding size
	optional uint32 kernelsize = 8; // The kernel size
	optional uint32 group = 9 [default = 1]; // The group size for group conv
	optional uint32 stride = 10 [default = 1]; // The stride
	enum PoolMethod {
	MAX = 0;
	AVE = 1;
	STOCHASTIC = 2;
	}
	optional PoolMethod pool = 11 [default = MAX]; // The pooling method
	optional float dropout_ratio = 12 [default = 0.5]; // dropout ratio

	optional uint32 local_size = 13 [default = 5]; // for local response norm
	optional float alpha = 14 [default = 1.]; // for local response norm
	optional float beta = 15 [default = 0.75]; // for local response norm
	optional float k = 22 [default = 1.];

	// For data layers, specify the data source
	optional string source = 16;
	// For data pre-processing, we can do simple scaling and subtracting the
	// data mean, if provided. Note that the mean subtraction is always carried
	// out before scaling.
	optional float scale = 17 [default = 1];
	optional string meanfile = 18;
	// For data layers, specify the batch size.
	optional uint32 batchsize = 19;
	// For data layers, specify if we would like to randomly crop an image.
	optional uint32 cropsize = 20 [default = 0];
	// For data layers, specify if we want to randomly mirror data.
	optional bool mirror = 21 [default = false];

	// The blobs containing the numeric parameters of the layer
	repeated BlobProto blobs = 50;
	// The ratio that is multiplied on the global learning rate. If you want to
	// set the learning ratio for one blob, you need to set it for all blobs.
	repeated float blobs_lr = 51;
	// The weight decay that is multiplied on the global weight decay.
	repeated float weight_decay = 52;

	// The rand_skip variable is for the data layer to skip a few data points
	// to avoid all asynchronous sgd clients to start at the same point. The skip
	// point would be set as rand_skip * rand(0,1). Note that rand_skip should not
	// be larger than the number of keys in the database.
	optional uint32 rand_skip = 53 [default = 0];

	// Fields related to detection (det_*)
	// foreground (object) overlap threshold
	optional float det_fg_threshold = 54 [default = 0.5];
	// background (non-object) overlap threshold
	optional float det_bg_threshold = 55 [default = 0.5];
	// Fraction of batch that should be foreground objects
	optional float det_fg_fraction = 56 [default = 0.25];

	// optional bool OBSOLETE_can_clobber = 57 [default = true];

	// Amount of contextual padding to add around a window
	// (used only by the window_data_layer)
	optional uint32 det_context_pad = 58 [default = 0];

	// Mode for cropping out a detection window
	// warp: cropped window is warped to a fixed size and aspect ratio
	// square: the tightest square around the window is cropped
	optional string det_crop_mode = 59 [default = "warp"];

	// For ReshapeLayer, one needs to specify the new dimensions.
	optional int32 new_num = 60 [default = 0];
	optional int32 new_channels = 61 [default = 0];
	optional int32 new_height = 62 [default = 0];
	optional int32 new_width = 63 [default = 0];

	// Whether or not ImageLayer should shuffle the list of files at every epoch.
	// It will also resize images if new_height or new_width are not zero.
	optional bool shuffle_images = 64 [default = false];

	// For ConcatLayer, one needs to specify the dimension for concatenation, and
	// the other dimensions must be the same for all the bottom blobs.
	// By default it will concatenate blobs along the channels dimension.
	optional uint32 concat_dim = 65 [default = 1];

	optional HDF5OutputParameter hdf5_output_param = 1001;
	}

	message PReLUParameter {
	// Parametric ReLU described in K. He et al, Delving Deep into Rectifiers:
	// Surpassing Human-Level Performance on ImageNet Classification, 2015.

	// Initial value of a_i. Default is a_i=0.25 for all i.
	optional FillerParameter filler = 1;
	// Whether or not slope parameters are shared across channels.
	optional bool channel_shared = 2 [default = false];
	}